SU953573A1 - Periodic electric signal stroboscopic conversion method - Google Patents

Description

(5) METHOD OF STROBOSCOPIC TRANSFORMATION OF PERIODIC ELECTRICAL SIGNALS

one

The invention relates to electrical measuring equipment and can be used in the study of periodic electrical signals with an unknown period of following.

The closest to the invention according to the technical essence is a method of strobe conversion of a periodic electric signal, consisting in asynchronous with the input signal of a pulse gating of this signal, in which all discrete values of the signal are read at the moments of gating and the sampling values and amplitude of the sweep voltage are read at gating 1 J.

The disadvantage of this method is the low conversion accuracy — it does not provide a given 20 number of samples per input signal period.

The purpose of the invention is to improve the conversion accuracy by providing a predetermined number of samples per input signal period.

Claims (1)

This goal is achieved by the fact that according to the method of strobe-conversion of periodic electrical signals, consisting in a gate-pulse of this signal, which is not synchronous with the input signal, which read all discrete values of the signal at the moments of strobe, form two calibration strobe pulses with unequal, previously known follow-up periods T and T, strobe the input signal with these strobe pulse sequences, convert the input signal samples by amplifying The extensions to the first and second converted signals form two pulse sequences with periods equal to the periods of the first and second converted signals, determine the number N of strobes of the first calibration sequence and the number p of periods of the pulse sequence formed from the first converted signal in the time interval between coincidence mi pulses of these sequences, determine the number N of strobe pulses of the second calibration sequence and the number of periods G impu For the sequence formed from the second transformed signal in the time interval between the coincidences of the pulses of these sequences, the value T of the period of the sampling pulses of the measuring sequence equal to T T N is calculated from the numbers obtained. P - N (y.) T T - rN where No. is a given number of samples for the period of the input signal, set the value of the period of the pulse. Equal to the calculated value, and receive the converted signal corresponding to the measuring sequence of strobe pulses. The drawing shows a structural electrical circuit of a variant of the device implementing the proposed method. The device consists of a controlled pulse generator 1, a mixer 2, an amplifier-expander 3, a match block k, a pulse sequence generator 5 with a period equal to the extended signal period, a pulse envelope generator 6, an extended period counter 7, a pulse counter 8 and a calculator 9. The method of real / is as follows. In the initial state, the counters 7 and 8, as well as the instrumentation of the calculator 9 are set to At the initial moment, the signal from the output of the calculator 9 turns on the strobe pulse generator and sets the period of the strobe pulses equal to T (first calibration cycle). With this, at the output of the amplifier-expander 3 an expanded signal appears, and at your output of the former 5 a pulse sequence with a period equal to the period of the extended signal. Pulses from the generator 1 output strobe pulses and from the output of the imaging unit 5 are fed to the inputs of the matching block i. This block forms the interval between the matches of the gating sequence pulses with a known period T with the pulses of the sequence formed by block 5 whose period is equal to the period of the extended signal. Since the strobe pulses and pulses of a period mapper 5 have a duration other than zero, at the output of the block C, matches instead of single pulses of coincidence there may appear bursts of coincidence pulses, which are smoothed by shaper 6 of the envelope of the pulses. When a pulse appears at the output of the imaging unit 6, the pulse counting by counters 7 and 8 is enabled. At the moment when the next pulse appears at the output of block 6, N counts are counted in counter 7, and the number P of the extended signal is counted in counter 8. This pulse in the form of N and. p, are read into and stored in calculator 9. After reading, counters 7 and 8 are set to O. At the same time, a signal appears at the output of calculator 9, which specifies the repetition period of generator 1 strobe pulses equal to T (the value of T is also known). This ends the first and begins the second calibration cycle, which is carried out similarly to the first. After the end of the second calibration cycle, the calculator 9 reads 1 - the number of periods of the extended signal corresponding to the period t of strobe pulses and N - the number of strobe pulses of the generator 1. Using the measured values of p, N, and N, the calculator 9 calculates the value of PN -,. (t - t) (1) T T g GPT "pN - rN j (From the output of calculator 9, the value T is fed to the control input of the generator 1 strobe pulses, according to which the period of strobe pulses is equal to t, which provides a given number of samples per period Signal under study. The proposed device allows to investigate periodic electric signals with an unknown period with automatic receipt of a predetermined number of samples for the period of the signal under investigation. Formula of invention The method of stroboscopic transformation of periodicals electrical signals closed in an asynchronous pulse-gating from the input signal of this signal, which reads all discrete values of the signal at the moments of gating, characterized in that, in order to increase the conversion accuracy by providing a predetermined number of samples for the period of the input signal, two calibration sequences are formed strobe pulses with unequal, previously known periods of following T and T strobe the input signal — these strobe pulse sequences The input signal is sampled by amplifying and expanding into the first and second transformed signals, form two pulse sequences with periods equal to the periods of the first and second converted signals, determine the number N of strobes of the first calibration sequence and the number p of periods of the pulse sequence generated from the first transformed signal. signal in the time interval between the coincidence of the pulses of these sequences, determine the number N of strobe pulses of the second calibration pulse The number of periods of the pulse sequence formed from the second transformed signal in the time interval between the coincidences of the pulses of these sequences is calculated from the numbers obtained, the value of the period c / 1 generation of the gating pulse of the measuring sequence equal to m – N p M –N / m – m pH -rN - I where N is a given number of samples for the period of the input signal, set the value of the period of the following strobe pulses equal to the calculated value and get the converted signal corresponding to measuring sequence of strobe pulses. Sources of information taken into account in the examination 1. AI Naidenov. Transformation of the spectrum of nanosecond pulses. M., Soviet Radio, 1973, p. 110 (prototype). -